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bird/lib/timer.c

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/*
* BIRD -- Timers
*
* (c) 2013--2017 Ondrej Zajicek <santiago@crfreenet.org>
* (c) 2013--2017 CZ.NIC z.s.p.o.
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
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/**
* DOC: Timers
*
* Timers are resources which represent a wish of a module to call a function at
* the specified time. The timer code does not guarantee exact timing, only that
* a timer function will not be called before the requested time.
*
* In BIRD, time is represented by values of the &btime type which is signed
* 64-bit integer interpreted as a relative number of microseconds since some
* fixed time point in past. The current time can be obtained by current_time()
* function with reasonable accuracy and is monotonic. There is also a current
* 'wall-clock' real time obtainable by current_real_time() reported by OS.
*
* Each timer is described by a &timer structure containing a pointer to the
* handler function (@hook), data private to this function (@data), time the
* function should be called at (@expires, 0 for inactive timers), for the other
* fields see |timer.h|.
*/
#include <stdio.h>
#include <stdlib.h>
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#include <time.h>
#include "nest/bird.h"
#include "lib/heap.h"
#include "lib/resource.h"
#include "lib/timer.h"
struct timeloop main_timeloop;
#ifdef USE_PTHREADS
#include <pthread.h>
/* Data accessed and modified from proto/bfd/io.c */
pthread_key_t current_time_key;
static inline struct timeloop *
timeloop_current(void)
{
return pthread_getspecific(current_time_key);
}
static inline void
timeloop_init_current(void)
{
pthread_key_create(&current_time_key, NULL);
pthread_setspecific(current_time_key, &main_timeloop);
}
void wakeup_kick_current(void);
#else
/* Just use main timelooop */
static inline struct timeloop * timeloop_current(void) { return &main_timeloop; }
static inline void timeloop_init_current(void) { }
#endif
btime
current_time(void)
{
return timeloop_current()->last_time;
}
btime
current_real_time(void)
{
struct timeloop *loop = timeloop_current();
if (!loop->real_time)
times_update_real_time(loop);
return loop->real_time;
}
#define TIMER_LESS(a,b) ((a)->expires < (b)->expires)
#define TIMER_SWAP(heap,a,b,t) (t = heap[a], heap[a] = heap[b], heap[b] = t, \
heap[a]->index = (a), heap[b]->index = (b))
static void
tm_free(resource *r)
{
timer *t = (void *) r;
tm_stop(t);
}
static void
tm_dump(resource *r)
{
timer *t = (void *) r;
debug("(code %p, data %p, ", t->hook, t->data);
if (t->randomize)
debug("rand %d, ", t->randomize);
if (t->recurrent)
debug("recur %d, ", t->recurrent);
if (t->expires)
debug("expires in %d ms)\n", (t->expires - current_time()) TO_MS);
else
debug("inactive)\n");
}
static struct resclass tm_class = {
"Timer",
sizeof(timer),
tm_free,
tm_dump,
NULL,
NULL
};
timer *
tm_new(pool *p)
{
timer *t = ralloc(p, &tm_class);
t->index = -1;
return t;
}
void
tm_set(timer *t, btime when)
{
struct timeloop *loop = timeloop_current();
uint tc = timers_count(loop);
if (!t->expires)
{
t->index = ++tc;
t->expires = when;
BUFFER_PUSH(loop->timers) = t;
HEAP_INSERT(loop->timers.data, tc, timer *, TIMER_LESS, TIMER_SWAP);
}
else if (t->expires < when)
{
t->expires = when;
HEAP_INCREASE(loop->timers.data, tc, timer *, TIMER_LESS, TIMER_SWAP, t->index);
}
else if (t->expires > when)
{
t->expires = when;
HEAP_DECREASE(loop->timers.data, tc, timer *, TIMER_LESS, TIMER_SWAP, t->index);
}
#ifdef CONFIG_BFD
/* Hack to notify BFD loops */
if ((loop != &main_timeloop) && (t->index == 1))
wakeup_kick_current();
#endif
}
void
tm_start(timer *t, btime after)
{
tm_set(t, current_time() + MAX(after, 0));
}
void
tm_stop(timer *t)
{
if (!t->expires)
return;
struct timeloop *loop = timeloop_current();
uint tc = timers_count(loop);
HEAP_DELETE(loop->timers.data, tc, timer *, TIMER_LESS, TIMER_SWAP, t->index);
BUFFER_POP(loop->timers);
t->index = -1;
t->expires = 0;
}
void
timers_init(struct timeloop *loop, pool *p)
{
times_init(loop);
BUFFER_INIT(loop->timers, p, 4);
BUFFER_PUSH(loop->timers) = NULL;
}
void io_log_event(void *hook, void *data);
void
timers_fire(struct timeloop *loop)
{
btime base_time;
timer *t;
times_update(loop);
base_time = loop->last_time;
while (t = timers_first(loop))
{
if (t->expires > base_time)
return;
if (t->recurrent)
{
btime when = t->expires + t->recurrent;
if (when <= loop->last_time)
when = loop->last_time + t->recurrent;
if (t->randomize)
when += random() % (t->randomize + 1);
tm_set(t, when);
}
else
tm_stop(t);
/* This is ugly hack, we want to log just timers executed from the main I/O loop */
if (loop == &main_timeloop)
io_log_event(t->hook, t->data);
t->hook(t);
tmp_flush();
}
}
void
timer_init(void)
{
timers_init(&main_timeloop, &root_pool);
timeloop_init_current();
}
/**
* tm_parse_time - parse a date and time
* @x: time string
*
* tm_parse_time() takes a textual representation of a date and time
* (yyyy-mm-dd[ hh:mm:ss[.sss]]) and converts it to the corresponding value of
* type &btime.
*/
btime
tm_parse_time(const char *x)
{
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struct tm tm = {};
int usec, n1, n2, n3, r;
r = sscanf(x, "%d-%d-%d%n %d:%d:%d%n.%d%n",
&tm.tm_year, &tm.tm_mon, &tm.tm_mday, &n1,
&tm.tm_hour, &tm.tm_min, &tm.tm_sec, &n2,
&usec, &n3);
if ((r == 3) && !x[n1])
tm.tm_hour = tm.tm_min = tm.tm_sec = usec = 0;
else if ((r == 6) && !x[n2])
usec = 0;
else if ((r == 7) && !x[n3])
{
/* Convert subsecond digits to proper precision */
int digits = n3 - n2 - 1;
if ((usec < 0) || (usec > 999999) || (digits < 1) || (digits > 6))
return 0;
while (digits++ < 6)
usec *= 10;
}
else
return 0;
tm.tm_mon--;
tm.tm_year -= 1900;
s64 ts = mktime(&tm);
if ((ts == (s64) (time_t) -1) || (ts < 0) || (ts > ((s64) 1 << 40)))
return 0;
return ts S + usec;
}
/**
* tm_format_time - convert date and time to textual representation
* @x: destination buffer of size %TM_DATETIME_BUFFER_SIZE
* @fmt: specification of resulting textual representation of the time
* @t: time
*
* This function formats the given relative time value @t to a textual
* date/time representation (dd-mm-yyyy hh:mm:ss) in real time.
*/
void
tm_format_time(char *x, struct timeformat *fmt, btime t)
{
btime dt = current_time() - t;
btime rt = current_real_time() - dt;
int v1 = !fmt->limit || (dt < fmt->limit);
if (!tm_format_real_time(x, TM_DATETIME_BUFFER_SIZE, v1 ? fmt->fmt1 : fmt->fmt2, rt))
strcpy(x, "<error>");
}
/* Replace %f in format string with usec scaled to requested precision */
static int
strfusec(char *buf, int size, const char *fmt, uint usec)
{
char *str = buf;
int parity = 0;
while (*fmt)
{
if (!size)
return 0;
if ((fmt[0] == '%') && (!parity) &&
((fmt[1] == 'f') || (fmt[1] >= '1') && (fmt[1] <= '6') && (fmt[2] == 'f')))
{
int digits = (fmt[1] == 'f') ? 6 : (fmt[1] - '0');
uint d = digits, u = usec;
/* Convert microseconds to requested precision */
while (d++ < 6)
u /= 10;
int num = bsnprintf(str, size, "%0*u", digits, u);
if (num < 0)
return 0;
fmt += (fmt[1] == 'f') ? 2 : 3;
ADVANCE(str, size, num);
}
else
{
/* Handle '%%' expression */
parity = (*fmt == '%') ? !parity : 0;
*str++ = *fmt++;
size--;
}
}
if (!size)
return 0;
*str = 0;
return str - buf;
}
int
tm_format_real_time(char *x, size_t max, const char *fmt, btime t)
{
s64 t1 = t TO_S;
s64 t2 = t - t1 S;
time_t ts = t1;
struct tm tm;
if (!localtime_r(&ts, &tm))
return 0;
size_t tbuf_size = MIN(max, 4096);
byte *tbuf = alloca(tbuf_size);
if (!strfusec(tbuf, tbuf_size, fmt, t2))
return 0;
if (!strftime(x, max, tbuf, &tm))
return 0;
return 1;
}